Developed applicability of a bacterial cellulose matrix as a gelling substitute for plant tissue culture media

Abstract

AbstractBacterial cellulose (BC) is a natural biodegradable, eco-friendly fiber, lying within the nanoscale range. It is reputable for its various physical and chemical qualities, like high hydrophilicity, immense crystallinity, ease of sterility, being toxin-free, and extremely pure. Adding to its wide applicability in different fields, this study evaluated the applicability of a developed gelling substitute for plant tissue culture media. The BC matrix was characterized under the acronym PLATIBACGEL (PLAnt TIssue Culture BActerial Cellulose GEL), formed by Komagataeibacter hansenii AS.5, preisolated from rotten apple waste. Scanning electron microscope, Fourier-transform infrared, X-ray diffractometer, and tensile strength analyses confirmed the formation of purified, porous, and heterogeneous densely packed multiple network polymers possessing cellulose properties. The water holding capacity (WHC) values of wet and dried BC membranes were 9179% and 226.9%, respectively, and the water absorption rate (WAR) of dry BC membranes was higher than that of wet membranes. Using BC as a tissue culture gelling agent, six genotypes from tomato and wheat seeds were cultured in vitro, for guaranteeing explant genetic diversity, over seven treatments. Treatment 5, included PLATIBACGEL as the main constituent, improved and sustained all in vitro seed germination, root penetration, and plant support. Likewise, repeated tomato micropropagation subcultures were successful. Results demonstrated applying PLATIBACGEL as a promising, reusable, cheap, and reliable alternative plant micropropagation media gelling agent. Wherefore, plant cellular developers and tissue-culturists can utilize bio-polymers like BC for better understanding plant cell response to different in vitro culturing conditions, with expected beneficial returns on gelling agents industry and markets as well. Graphical abstract